JP4727485B2 - Optical transmission equipment - Google Patents

Description

  The present invention relates to an optical transmission apparatus in which signal light is added / dropped and the number of signal wavelengths is arbitrarily changed.

With the development of multimedia networks, the demand for communication traffic has increased dramatically, and the WDM (Wavelength Division Multiplexing) transmission system that multi-amplifies optical signals using optical amplifiers has made the communication system more economical in the multimedia society. It plays a big role in planning.

  In recent years, WDM systems have been actively introduced for urban metro core networks where cost and size are important. Along with this, introduction of an optical add / drop multiplexer (OADM) is progressing in each station constituting the WDM system.

A conventional configuration of an OADM device (node) as an optical transmission device is shown in FIG. As an optical circuit configuration, the WDM signal light and the SV (Supervisory) light (supervisory signal light) sent from the transmission line are converted into the SV.
Only the light is demultiplexed by the SV filter 1 and converted into an electric signal by the O / E (optical / electrical) converter 2.

The WDM signal light is demultiplexed into each channel (ch) using an AWG (Arrayed Waveguide Grating) 3. Further, signal light is added / dropped by the optical switch 4 for each channel. The added or passed signal light is multiplexed again by the AWG 5.

The combined WDM signal light is sent from an EDFA (Erbium-Doped Fiber-Optical Amplifier) 9 equipped with a duplexer 7 and a photodetector 8 for monitoring the input power to the amplifier 6. After being amplified, it is combined with the SV light generated by the E / O (electric / optical) converter 10 by the multiplexer 11 and then sent to the transmission line.

  As for the control circuit, information about which node is dropped for each channel (dropped) transferred from the upstream node from the monitoring signal obtained by the O / E conversion of the SV light by the O / E converter 2. Node number) is obtained by the node number information receiving circuit 12. For each channel, the node number information receiving circuit 12 determines how many ASE (Amplified Spountaneous Emission) light has arrived at its own node via the drop node number (number of nodes through which the ASE has passed: ASE transmission node) Number).

  From such ASE information and the relational expression (block 14 in FIG. 8) of the number of ASE transmission nodes and ASE power stored in advance as information in the node, the ASE power calculation circuit 15 calculates the ASE power of each channel. And the sum of the ASE power of each channel is calculated. Such ASE power information is sent to the EDFA 9. Further, from the monitoring signal obtained by the O / E converter 2, the number of wavelengths including the signal is calculated by the wavelength number information receiving circuit 13, and the wavelength number information is sent to the EDFA 9. These pieces of information are input to the ALC target value determination circuit 16 provided in the EDFA 9.

The ALC target value determination circuit 16 is supplied from the amplifier 6 on the basis of the ASE power information, the wavelength number information, and the input total power (S (signal) + ASE) information obtained by the input power detector 8 of the EDFA 9. Output total power (S) so that the signal output of each channel is constant.
A control target value (ALC (Automatic Level Control) target value) of + ASE) is calculated and determined.

  The amplifier 6 includes an ALC control circuit, and the ALC control circuit outputs an output for controlling the gain of the amplifier 6 so that the power (output total power) of the signal light output from the amplifier 6 becomes the ALC target value. Constant control (ALC) is performed.

  Note that the drop node number obtained by the node number information receiving circuit 12 and the information indicating that the signal has been dropped by the SW 4 (the node number of the own node as the drop node number) are sent to the node number information transmitting circuit 17. And transmitted to the E / O converter 10 as node number information. Further, the wavelength number information obtained by the wavelength number information receiving circuit 13 and information indicating that a signal has been added by the SW 4 (wavelength information added by the own node) is given to the wavelength number information transmitting circuit 18. The wavelength number information transmission circuit 18 inputs the wavelength number information to the E / O converter 10. The E / O converter 10 generates SV light including node number information and wavelength number information and sends it to the multiplexer 11.

As a prior art document related to the present invention, for example, there is a technique disclosed in Patent Document 1 below.
Japanese Patent Laid-Open No. 2000-4213

However, in the prior art shown in FIG. 8, node number information and wavelength number information are obtained using the SV channel in order to obtain ASE power information as a parameter for determining the ALC target value. Therefore, the SV channel, the O / E converter 2 and the E / O converter 10 for the SV channel, the node number reception circuit 12, the wavelength number information reception circuit 13, the node number transmission circuit 17, and the wavelength number information transmission circuit 18 Such an electric circuit for transmitting / receiving node number information and wavelength number information to / from adjacent nodes is required. Furthermore, communication between nodes (S
In order to transmit and receive V light, a complex system is required that requires multiplexing / demultiplexing of the SV light with respect to the WDM signal.
Further, the information by the SV light is sequentially transferred from the most upstream node through the SV light transmitting / receiving circuit provided at each node. Due to this property, a transfer time of about several hundreds [ms] is required, and there is a possibility that the ALC control is delayed by the transfer time.

  In general, since ASE occurs in the amplification band of the optical amplifier, it is possible to monitor ASE at a wavelength outside the signal band including the channel. However, in the conventional technique shown in FIG. In the process of demultiplexing to each channel by AWG3 and recombining by AWG5, light outside the signal band including the channel is not output, so ASE cannot be monitored at a wavelength outside the signal band including the channel. .

  An object of the present invention is to provide an optical transmission apparatus capable of appropriate output constant control while simplifying the configuration.

  The present invention employs the following means in order to achieve the above-described object.

That is, the present invention comprises means for measuring the optical power of each wavelength included in the wavelength multiplexed signal;
Means for comparing the measured value of the optical power of each wavelength with a predetermined threshold;
Means for calculating a total value of measured values of optical power equal to or higher than a threshold as a total value of signal light power;
Means for calculating a total value of optical power measurements below a threshold value as a total value of ASE power;
Means for calculating the number of measured values of optical power equal to or greater than a threshold as the number of wavelengths of signal light included in the wavelength multiplexed signal;
Means for calculating a ratio of the total value of the signal light power and the total value of the ASE power and a signal-to-ASE ratio;
An optical amplifier for amplifying the wavelength division multiplexed signal;
Means for measuring the optical power of the wavelength multiplexed signal input to the optical amplifier;
In order to carry out output constant control of the optical amplifier in which the optical power of each wavelength in the wavelength multiplexed signal output from the optical amplifier is constant, the number of wavelengths, the signal-to-ASE ratio, and the light of the wavelength multiplexed signal Means for determining a target value for the constant output control using a measured power value.

  According to the present invention, it is determined whether light of each wavelength included in the wavelength multiplexed signal is signal light or ASE light using a threshold, and the total value of the optical power of the signal light and the total value of the optical power of the ASE light The S / ASE ratio is calculated based on the above. Further, the number of wavelengths is calculated from the number of measured values of signal light.

  As described above, in the optical transmission apparatus according to the present invention, the parameter for obtaining the target value of constant output control (ALC) is generated in the own apparatus from the wavelength multiplexed signal, not from the SV channel information. For this reason, the complicated structure which exchanges a monitoring signal using an adjacent node and SV channel like a prior art is not required. That is, the configuration of the optical transmission device is simplified.

  In addition, since the parameter for obtaining the target value of the constant output control is generated in the own apparatus, the constant output control is not delayed due to the arrival delay of the monitoring signal as in the prior art. That is, the speed of the constant output control can be increased.

Preferably, the optical transmission device according to the present invention includes a duplexer that demultiplexes the wavelength-multiplexed signal into light for each channel;
An add / drop unit that is disposed on an optical path through which light of each channel demultiplexed by the demultiplexer passes, drops signal light that passes through the optical path, and adds signal light to the optical path;
A multiplexer that generates a wavelength multiplexed signal obtained by multiplexing the light of each channel that has passed through the add / drop unit;
The means for measuring the optical power of each wavelength is disposed on the optical path downstream of each add / drop unit, and the light passing through the optical path is divided into a first direction and a second direction toward the multiplexer. A branching section for branching and a light detecting section for detecting the power of the light branched in the second direction.

Preferably, the optical transmission apparatus according to the present invention includes a branching unit that branches the wavelength multiplexed signal in two directions,
A first wavelength selective switch that selects and drops signal light of a predetermined wavelength included in a wavelength multiplexed signal branched in one direction from the branching unit;
A second wavelength selective switch for adding signal light of a predetermined wavelength to the wavelength multiplexed signal branched in another direction from the branching unit;
The means for measuring the optical power of each wavelength includes an optical channel monitor for measuring the optical power of each wavelength included in the wavelength multiplexed signal output from the second wavelength selective switch.

  ADVANTAGE OF THE INVENTION According to this invention, the optical transmission apparatus which enables appropriate output constant control can be provided, simplifying a structure.

  Further, even when a device such as AWG that does not output light out of the signal band including the channel is used, the ASE amount can be measured and appropriate output constant control can be performed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The configuration of the embodiment is an exemplification, and the present invention is not limited to the configuration of the embodiment.

[Outline of Embodiment]
1 and 2 are diagrams showing a configuration example (optical transmission apparatus 20) of an optical transmission apparatus (OADM apparatus (node)) according to an embodiment of the present invention. The optical transmission device 20 is arranged on the WDM signal transmission path together with other nodes in a state of being connected in series with the other nodes.

In FIG. 1, the optical transmission apparatus 20 has the following configuration as an optical circuit configuration. An AWG 21 as a duplexer is connected to the upstream transmission path. The AWG 21 receives a WDM signal (wavelength multiplexed signal) from the transmission path. The AWG 21 demultiplexes the WDM signal into each channel (wavelength: channel number n (n is a natural number excluding 0)).

An optical switch (SW) 22 as an add / drop unit is disposed on the optical path of light corresponding to each channel. The SW 22 is prepared for each channel (however, in FIG.
Only one SW22 is shown). The SW 22 drops light of the corresponding wavelength to the own node, or adds light of the corresponding wavelength from the own node.

  On the optical path on the output side of the SW 22, an optical splitter 23 (branching unit) that branches a part of the light emitted from the SW 22 in two directions is provided. The light branched in one direction (first direction) from the optical splitter 23 enters an AWG 24 as a multiplexer that multiplexes a plurality of channels. On the other hand, the light branched in the other direction (second direction) from the optical splitter 23 is incident on a photo detector (PD: Photo Detector (Photo Diode)) 25. The optical splitter 23 and the PD 25 are prepared for each channel.

  The WDM signal combined by the AGW 24 is incident on the EDFA 26. The EDFA 26 splits the WDM signal incident from the AWG 24 in two directions, an optical amplifier 28 to which the WDM signal branched in one direction from the optical splitter 27, and the optical splitter 27 branched in the other direction. And a photodetector (PD) 29 to which a WDM signal is input. The optical amplifier 28 amplifies and emits the incident WDM signal. The WDM signal emitted from the optical amplifier 28 is sent to the downstream transmission path.

  The optical transmission device 20 has the following configuration as a control circuit configuration. That is, as shown in FIG. 2, the optical transmission apparatus 20 includes a plurality of signal presence / absence detection circuits 30 connected to the PD 25 for each channel. The plurality of signal presence / absence detection circuits 30 are connected to a wavelength number calculation circuit 31, a signal power calculation circuit 32, and an ASE power calculation circuit 33. The signal power calculation circuit 32 and the ASE power calculation circuit 33 are connected to the S / ASE ratio calculation circuit 34. The S / ASE ratio calculation circuit 34 is connected to an ALC target value determination circuit 35 provided in the EDFA 26. The ALC target value determination circuit 35 is connected to the PD 29.

  Each PD 25 detects incident light (converts it into an electrical signal) and monitors (measures) the optical power of the channel. The measured value (monitor value) of the optical power is input to the corresponding signal presence / absence detection circuit 30.

The signal presence / absence detection circuit 30 has a predetermined threshold value, and determines the presence / absence of signal light of the channel based on whether or not the measured value of the input optical power exceeds the threshold value. The signal presence / absence detection circuit 30 compares the measured value with a threshold value. At this time, if the measured value exceeds the threshold value, the signal presence / absence detection circuit 30 determines that there is signal light in the channel, and outputs the measured value to the wavelength number calculation circuit 31 and the signal power calculation circuit 32. On the other hand, if the measured value does not exceed the threshold value, the signal presence / absence detection circuit 30 determines that there is no signal light in the channel (only ASE light), and outputs the measured value to the ASE power calculation circuit 33. .

  The wavelength number calculation circuit 31 calculates the number of wavelengths of the WDM signal amplified by the EDFA 26 by counting the number of measurement values input from the signal presence / absence detection circuit 30. The wavelength number calculation circuit 31 inputs the calculated wavelength number to the ALC target value determination circuit 35 as a determination unit.

  The signal power calculation circuit 32 calculates the total value of the measurement values input from the signal presence / absence detection circuit 30 and inputs this total value to the S / ASE ratio calculation circuit 34 as the total signal light power. The ASE power calculation circuit 33 calculates the total value of the measurement values input from the signal presence / absence detection circuit 30, and inputs this total value to the S / ASE ratio calculation circuit 34 as the total ASE power.

  The S / ASE ratio calculation circuit 34 calculates the S / ASE ratio (signal to ASE ratio) from the ratio between the total signal light power and the total ASE power, and inputs the S / ASE ratio to the ALC target value determination circuit 35.

In addition to the number of wavelengths and the S / ASE ratio, the ALC target value determination circuit 35 uses the input total power (S ( Signal) + ASE). The ALC target value determining circuit 35 uses these pieces of information to output the total power control target value (A
LC target value) is calculated and determined.

  The optical amplifier 28 includes an ALC control circuit, and the ALC target value determined by the ALC target value determination circuit 35 is set in the ALC control circuit. The ALC control circuit performs ALC control based on the ALC target value. That is, the ALC control circuit makes an error between the WDM signal (optical output) output from the optical amplifier 28 and the ALC target value so that the signal output of each channel is constant in the WDM signal output from the optical amplifier 28. The gain of the optical amplifier 28 is controlled accordingly.

According to the optical transmission apparatus 20, the supervisory signal channel (SV) as described in the prior art (FIG. 8) is used.
(Channel) and electric circuits related thereto (O / E converter, E / O converter, node number information reception / transmission circuit, wavelength number information reception / transmission circuit) are omitted. In addition, the configuration for transmitting and receiving SV light between adjacent nodes is also omitted. Therefore, the apparatus configuration is simplified as compared with the prior art.

Furthermore, in the optical transmission device 20, since the exchange of information for calculating the ALC target value is closed within the own node, a sufficiently high ALC control speed of about several tens [μs] can be realized.

〔Concrete example〕
As a specific example, details (specific example) of the optical transmission device 20 illustrated in FIGS. 1 and 2 will be described. It is assumed that the maximum number of wavelengths applied to the optical transmission apparatus 20 is 40 waves, and the number of transmission nodes until reaching the optical transmission apparatus 20 (own node) is 16 nodes. The bandwidth of the AWGs 21 and 24 is 0.1 [n
m]. The reception OSNR (optical signal-to-noise ratio) in one-node transmission is 26 [dB], and the signal light power at the photodetector (PD) 23 is −10 [dBm / ch].

Further, a case as shown in FIG. 3 is assumed as a representative pattern in which the spectral shape of the ASE incident on the EDFA 26 is complicated. That is,
(1) The signal light exists only in the channel (Ch) 1 and is transmitted in 16 nodes.
(2) There is no signal light in Ch6, 11, 16, 21, 26, 31, 36, and only ASE is transmitted in 16 nodes.
(3) In Ch7,12,17,22,27,32,37, the signal light is dropped after 8-node transmission, then A
Only SE is transmitted in 8 nodes.
(4) In Ch8, 13, 18, 23, 28, 33, 38, the signal light is dropped after 12-node transmission,
Only ASE is transmitted in 4 nodes.
(5) In Ch9, 14, 19, 24, 29, 34, 39, the signal light is dropped after 14-node transmission, and then
Only the ASE is transmitted in two nodes.
(6) In Ch10, 15, 20, 25, 30, 35, 40, the signal light is dropped after 15 nodes are transmitted, and then only ASE is transmitted for 1 node.

  The number of transmission nodes and the OSNR have a relationship represented by the graph shown in FIG. Further, the number of transmission nodes and the ASE power detected by the PD 23 of each channel have a relationship represented by the graph shown in FIG.

  FIG. 6 is a graph showing the spectrum of signal light and ASE power detected by the PD 23 of each channel. A WDM signal (signal light + ASE) having such a spectrum is input to the EDFA 26.

  The threshold value set in each signal presence / absence detection circuit 30 is determined as follows, for example. That is, as shown in FIG. 5, ASE is -24 [dBm] or less even if 16 nodes are transmitted. For this reason, a numerical value of −24 [dBm] or more is determined as the threshold value. In this example, −23 [dBm] is determined as the threshold value.

  If the light reception power at the PD 23 is −23 [dBm] or more, the signal presence / absence detection circuit 30 determines that the light reception power (measured value) is signal light power (that is, the channel has signal light). On the other hand, if the received light power is less than −23 [dBm], the signal presence / absence detection circuit 30 determines that the received light power is only ASE power (that is, the channel has no signal light). With such a threshold, the presence or absence of signal light in each channel is detected.

The signal power calculation circuit 32 calculates the total power (total signal light power) of the channel in which the signal light exists. In this example, the total signal light power calculated by the signal power calculation circuit 32 is −9.8 [dBm].

The ASE power calculation circuit 33 calculates the total power (total ASE power) of a channel in which no signal light exists. In this example, the total ASE power calculated by the ASE power calculation circuit 32 is −12.1 [dBm].

  The S / ASE ratio calculation unit 34 calculates the S / ASE ratio from the ratio of the total signal light power and the total ASE power. In this example, the S / ASE ratio calculated by the S / ASE ratio calculation unit 34 is 2.1 [dB].

Furthermore, the wavelength number calculation circuit 31 calculates the total value of channels in which signal light exists (the total value of received light power measurement values equal to or greater than a threshold value) as the number of wavelengths. In this example, the wavelength number calculated by the wavelength number calculation circuit 31 is 1 [wave]. These S / ASE ratio and the number of wavelengths are input to the ALC target value determination circuit 35 of the EDFA 26.

The ALC target value determination circuit 35 of the EDFA 26 calculates an ALC target value based on the S / ASE ratio, the number of wavelengths, and the total input power from the PD 29. First, the ALC target value determination circuit 35 calculates “Pase_in” using the following <Equation 1>. “Pase_in” is ASE power input to the optical amplifier 28.

Pase_in [mW] = Ptotal_in [mW] / (1+ (S / ASE [true number]) ・ ・ ・ <Formula 1>
In <Formula 1>, “Ptotal_in” indicates the input total power (S + ASE) input to the optical amplifier 28, which is input from the monitor PD (PD29) on the input side of the optical amplifier 28. “S / ASE” indicates the S / ASE ratio input from the S / ASE ratio calculation circuit 34. In this example, “Ptotal_in” is 0.01 [mW]. Therefore, “Pase_in” calculated by the ALC target value determination circuit 35 is 0.0038 [mW].

  Next, the ALC target value determination circuit 35 calculates “Psig_in” using the following <Equation 2>. “Psig_in” is the signal light power input to the optical amplifier 28.

Psig_in [mW / ch] = (Ptotal_in [mW] − Pase_in [mW]) / (number of wavelengths) (Formula 2)
In this example, “Psig_in” calculated by the ALC target value determination circuit 35 is 0.0061 [mW / ch].

Next, the ALC target value determination circuit 35 calculates “Pase_out” using the following <Equation 3>. “Pase_out” is an output A when ASE is not included in the input of the optical amplifier 28.
Indicates SE power.

Pase_out [dBm] = a * Psig_in [dBm / ch] ^ 2 + b * Psig_in [dBm / ch] + c (Formula 3)
In <Expression 3>, the symbol "^" indicates that the subsequent character is an exponent (the same applies to <Expression 6> described later). In addition, the coefficients “a”, “b”, and “c” in <Expression 3> are parameters that change depending on the ASE noise characteristics of the EDFA. In the case of the EDFA 26 used in this example, a = 0.0937, b = 3.3786, c = 18.9855. Therefore, “Pase_out” calculated by the ALC target value determination circuit 35 is −10 [dBm].

  Next, the ALC target value determination circuit 35 calculates “Ek” using the following <Equation 4>. “Ek” is an ASE correction value of the optical amplifier 28 alone when ASE is not included in the input of the optical amplifier 28.

Ek [dB] = 10 * log (1 + Pase_out [mW] / Psig_out target value [mW])
= 10 * log (1+ (Pase_out [mW] / (Psig_out target value [mW / ch] * (number of wavelengths))) (Formula 4)
In this example, the Psig_out target value (signal output target value) is 1.0 [mW / ch]. For this reason, “Ek” calculated by the ALC target value determination circuit 35 is 0.42 [dB].

  Next, the ALC target value determination circuit 35 calculates a “Gsig target value” using <Formula 5> shown below. “Gsig target value” is a target value of signal gain.

Gsig target value [dB] = Psig_out target value [dBm / ch] −Psig_in [dBm / ch] (Formula 5)
In this example, the “Gsig target value” calculated by the ALC target value determination circuit 35 is 22.1 [dB].

  Next, the ALC target value determination circuit 35 calculates “Ptotal_out target value” using <Formula 6> shown below. “Ptotal_out target value” is an output total power control target value of the optical amplifier 28, that is, an ALC target value such that the signal output of each channel becomes constant.

Ptotal_out target value [mW] = 10 ^ ((Psig_out target value [dBm] + Ek [dB]) / 10)
+10 ^ ((Pase_in [dBm] + Gsig target value [dB]) / 10) ・ ・ ・ <Formula 6>
In this example, the “Ptotal_out target value” calculated by the ALC target value determination circuit 35 is 1.72 [mW]. The “Ptotal_out target value” is set in the ALC control circuit of the optical amplifier 28, and the ALC control circuit performs ALC control based on the “Ptotal_out target value”.

  As described above, the ALC control in consideration of the ASE generated at the output of the optical amplifier 28 is performed, so that a constant value is obtained for each channel regardless of the number of wavelengths and the node where the signal light is dropped. It becomes possible to maintain the signal output.

Next, in the specific example described above, the characteristics required for the PD 23 of each channel are as follows. That is, the maximum light receiving power is -24 [dB] which is the ASE power after 16 nodes transmission.
m] and −10 [dBm], which is the signal light power, is −9.8 [dBm]. Also,
The minimum received light power is −36 [dBm], which is the ASE power after one-node transmission. Therefore, the required dynamic range is 26.2 [dB]. This is a sufficiently realizable characteristic.

<Second configuration example>
FIG. 7 is a diagram illustrating a second configuration example (optical transmission apparatus 40) of the optical transmission apparatus according to the embodiment of the present invention. In FIG. 7, the same components as those of the optical transmission device 20 (first configuration example) shown in FIG.

In the optical transmission device 40, instead of the AWG 21, SW 22 and AWG 24 in the optical transmission device 20, an optical splitter 41 as a branching unit, a drop WSS (Wavelength Selecting Switch) 42 (first wavelength selective switch) , And WSS 43 (second wavelength selective switch) for add. The optical transmission device 40 has an OCM (Optical Channel Monitor) 44 (optical channel monitor unit) instead of the optical splitter 23 and the PD 25 in the optical transmission device 20.

The optical splitter 41 distributes the WDM signal (signal light + ASE) from the upstream transmission path to the WSS 42 and the WSS 43. The WSS 42 selects and drops light of a wavelength (channel) to be dropped at its own node (optical transmission device 40). The WSS 43 is connected to its own node (optical transmission device 4
In 0), the wavelength to which the signal light is to be added is selected to add the signal light.

  The OCM 44 monitors (measures) the optical power in each channel (1 to n), and sends the measured value of the optical power in each channel to the wavelength number calculation circuit 31A, the signal power calculation circuit 32A, and the ASE power calculation circuit 33A. input.

  The wavelength number calculation circuit 31 has a threshold value for determining the presence or absence of signal light described in the first configuration example, and compares the optical power (measured value) of each channel input from the OCM 44 with the threshold value. The number of measured values equal to or greater than the threshold is counted, the total value is calculated as the number of wavelengths, and is input to the ALC target value determining circuit 35.

  The signal power calculation circuit 32A has a threshold for determining the presence or absence of the signal light described in the first configuration example, and compares the optical power (measured value) of each channel input from the OCM 44 with the threshold. The total value of the measured values equal to or greater than the threshold is calculated as the total signal power and input to the S / ASE ratio calculation circuit 34.

  The signal power calculation circuit 33A has a threshold for determining the presence or absence of signal light described in the first configuration example, and compares the optical power (measured value) of each channel input from the OCM 44 with the threshold. The total value of the measured values less than the threshold is calculated as the total ASE power and input to the S / ASE ratio calculation circuit 34.

  The configurations of the S / ASE ratio calculation circuit 34 and the EDFA 26 are the same as those in the first configuration example (the optical transmission device 20). In the EDFA 26, in the output from the optical amplifier 28 by the method described for the first configuration example. ALC control is executed so that the signal output of each channel is constant.

FIG. 1 is a diagram illustrating a first configuration example of an optical transmission apparatus according to an embodiment of the present invention. FIG. 2 is a diagram illustrating a control circuit configuration of the optical transmission apparatus illustrated in FIG. FIG. 3 is a diagram showing a representative pattern in which the spectral shape of the ASE incident on the EDFA is complicated. FIG. 4 is a graph showing the relationship between the number of transmission nodes and the OSNR. FIG. 5 is a graph showing the relationship between the number of transmission nodes and the ASE power detected by the photodetector of each channel. FIG. 6 is a graph showing a spectrum of signal light and ASE power detected by the photodetector of each channel. FIG. 7 is a diagram illustrating a second configuration example of the optical transmission apparatus according to the embodiment of the present invention. FIG. 8 is a diagram illustrating a configuration example of an optical transmission device according to a conventional technique.

Explanation of symbols

20, 40 ... Optical transmission equipment (OADM equipment)
21, 24 ... AWG
22 ... Optical switches 23, 27 ... Optical splitters 25, 29 ... Optical detector (PD)
28 ... Optical amplifier 30 ... Signal presence / absence detection circuit 31, 31A ... Wavelength number calculation circuit 32, 32A ... Signal power calculation circuit 33, 33A ... ASE power calculation circuit 34 ... S / ASE ratio calculation circuit 35... ALC target value determination circuit

Claims (3)

A demultiplexer that inputs a wavelength-multiplexed signal and demultiplexes it into light for each channel;
Means for measuring the optical power of each wavelength in each of the demultiplexed channels;
A multiplexer for generating a wavelength multiplexed signal obtained by multiplexing the demultiplexed light;
An optical amplifier for amplifying the combined wavelength multiplexed signal;
Means for comparing the measured value of the optical power of each wavelength with a predetermined threshold;
Means for calculating a total value of measured values of optical power equal to or higher than a threshold as a total value of signal light power;
Means for calculating a total value of optical power measurements below a threshold value as a total value of ASE power;
Means for calculating the number of measured values of optical power equal to or greater than a threshold as the number of wavelengths of signal light included in the wavelength multiplexed signal;
Means for calculating a ratio of the total value of the signal light power and the total value of the ASE power as a signal-to-ASE ratio;
Means for measuring the optical power of the wavelength multiplexed signal input to the optical amplifier;
In order to carry out output constant control of the optical amplifier in which the optical power of each wavelength in the wavelength multiplexed signal output from the optical amplifier is constant, the number of wavelengths, the signal-to-ASE ratio, and the light of the wavelength multiplexed signal Means for determining a target value for the constant output control using a measured power value. The signal light is disposed between the demultiplexer and the multiplexer on the optical path through which the demultiplexed light passes, and the signal light is dropped through the optical path, and the signal light is added to the optical path. An add / drop unit for performing
The means for measuring the optical power of each wavelength is disposed on the optical path downstream of each add / drop unit, and the light passing through the optical path is divided into a first direction and a second direction toward the multiplexer. The optical transmission device according to claim 1, comprising: a branching unit that branches and a light detection unit that detects power of light branched in the second direction. A branching section for branching the wavelength multiplexed signal in two directions;
A first wavelength selective switch that selects and drops signal light of a predetermined wavelength included in a wavelength multiplexed signal branched in one direction from the branching unit;
A second wavelength selective switch for adding signal light of a predetermined wavelength to the wavelength multiplexed signal branched in another direction from the branching unit;
The means for measuring the optical power of each wavelength includes an optical channel monitor that measures the optical power of each wavelength included in the wavelength multiplexed signal output from the second wavelength selective switch. Optical transmission device.

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